JPH0544231B2 - - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a lens system correction information creation method for creating lens system correction information for use in a plurality of television cameras using a test camera having a lens system and an imaging device on the optical path. It is.

Such a method is disclosed in US Pat. No. 4,285,004, in which a test pattern present on a test diagram is placed in front of a color television camera. Optical information emerging from the test diagram is supplied to a pickup device via an optical path including a lens system and a color separation prism. This pickup device includes three pickup devices, each of which outputs a color signal as a video signal. After the setup operation, a correction signal is applied to two or all three pick-up devices, resulting in an optimal raster registration ratio for the receiving television image.
registration) is obtained. In addition, during setup, the sizing error at the black level and the maximum video value are corrected, and gamma correction is obtained by supplying a correction signal to the video signal processing circuit.

In practice, it is extremely troublesome for the camera operator to set up a television camera using a test diagram placed some distance in front of the camera. Positioning the test figure in the correct position and under suitable lighting must always be done by hand, which is time consuming and tedious for the camera operator.

An object of the present invention is to provide a lens system correction information creation method that does not require a television camera operator to position a test diagram displaying a test pattern in front of the camera when preparing to record a scene under normal conditions. It is in.

According to the present invention, in order to achieve this objective, an internal test pattern is placed in the optical path between the lens system and the imaging device while blocking light incident on the lens system, and this internal test pattern is used with a test camera. An image is taken to create an internal test pattern correction signal, the internal test pattern correction signal is stored in a camera memory, an external test pattern is imaged by a test camera through a lens system to create an external test pattern correction signal, and the external test pattern is imaged by a test camera through a lens system. The present invention is characterized in that an internal test pattern correction signal is subtracted from an external test pattern correction signal to generate a lens system correction signal representing lens system correction information, and this lens system correction signal is stored in a lens memory.

The method described above performs setup in two steps. Under normal circumstances, the camera operator only needs to perform a setup using an internal test pattern provided within the camera when preparing to record a scene. This internal test pattern is in the form of a pivotable slide illuminated by a light source and can be placed in the optical path between the (optically blocked) lens system and the camera pickup device. Alternatively, the slide can be brought into the optical path by means of a mirror. Prior to this, the camera supplier, who prepares various lenses for the camera, performs an individual setup for each lens system using, for example, an external test pattern placed in front of the camera. Differences between correction information related to various lens systems determined by external test patterns and correction information related to internal test patterns are stored, for example, in a digital lens memory. As a result, each lens system has its own lens memory in which correction information is stored. All the camera operator has to do to set up the camera when preparing to record a scene is to select the appropriate lens memory associated with the lens system within the camera, i.e. one of the built-in lens memories. Automatic setup can be performed by selecting the illumination light path, blocking the light path including the lens system, and then positioning the test pattern present in the camera in the illumination light path. If the setup is fully automatic, the camera operator only needs to operate one nozzle on the camera.

The method described above can be performed functionally separately for each lens system. Therefore, setup using the external test pattern and internal test pattern is performed separately to load the correction difference information into the associated lens memory, and then when the television camera is used, only the internal test pattern in the camera is required for setup. becomes. Loading correction information into the memory for the lens system can be done by the lens system supplier (manufacturer);
Alternatively, it can be done by the camera operator himself instead of by the lens system supplier. When a camera operator stores correction information in a lens memory, if the lens memory information is refreshed at appropriate time intervals, even if the lens system undergoes an aging phenomenon, it can be compensated for.

The invention will be further explained below.

For example, when loading into a digital memory that is intended to be related to one of the lens systems, the correction information related to the external test pattern displayed on the test diagram is temporarily separated to form the correction information related to the lens system. can be stored in memory.
In this case, there is an advantage that the loading of the lens memory does not have to be performed simultaneously with the creation of correction information related to the test diagram pattern. Since it is a temporary memory, the correction difference information can be formed at any desired instant by a microcomputer. Thereafter, the contents of the separate memory can also be erased.

In the method described above, the lens memory contains correction information relating (purely) to the lens system, but this memory also stores correction information regarding errors in the blocked part of the optical path in which the lens system is arranged. You can grow it.

Using the method of the invention, the camera memory used by the camera operator during the setup operation (which is part of the preparation for recording) and the correction information relating to at least the lens system used at that moment in the camera A television camera is obtained which includes a lens memory storing the information. If a camera is suitable for studio recording and outdoor recording, and the camera is equipped with the necessary lens systems for this purpose, a lens system that has range extension features will have different characteristics than the same lens that lacks this feature. 8 lens memories are sufficient to store the various items of correction information.

A memory and lens system using the method of the invention can be provided to the user of the camera. After equipping the camera with a lens system and connecting the lens memory containing correction information regarding this lens system to the microcomputer, or after making a selection between the built-in memories, the camera operator can record the scene. Setup can be done using internal test patterns for preparation.

In practice, electronic or non-electronic identification features are formed in the lens memory containing the associated lens system and correction information.

According to the method of the invention, the memory stores correction information for an associated lens system for a (eg color) television camera. When recording, color television cameras process the green, red, and blue components of the light coming from the scene being imaged. For example, a digital lens memory can store correction information for, for example, shape, registration or raster registration, shading distortion, optical focus, and video signals. The geometric correction may be pincushion-shaped or barrel-shaped and may be characterized by a single coefficient stored in a digital memory. Optical focus correction can be accomplished by writing three coefficients into memory. If the overlay error is expressed as a dimensional error of red and blue relative to green, two coefficients are required for correction. The shading distortion can be caused by, for example, red, green and blue horizontal and vertical corrections, parabolic and sawtooth corrections, and therefore it is necessary to store 12 coefficients in the lens memory. Higher order corrections require more coefficients. In the case of video signal correction, it is suitable for the idea of amplifying red and green and correcting the black level. This requires 4 coefficients.

When determining lens correction is performed using an external test pattern and an internal test pattern, the internal test pattern needs to have the same configuration as the external test pattern. On the other hand, if a television camera user purchases a lens system that includes a memory that already stores correction information about the lens system, the camera operator can perform color correction using various internal test patterns and The correction information and stored lens correction information can be combined.

The invention will be explained by way of example and with reference to the drawings.
However, the present invention is not limited to this example.

The drawing shows an external test pattern 1 existing on a test diagram, and this test diagram is positioned on the front side of a television camera 2. The optical information generated from the test diagram is supplied to a pick-up mounting 5 via an optical path 3 with a lens system 4 on the way.
The pick-up mount 5 converts this optical information into electrical information and supplies it to a video processing circuit 6. The above conversion is carried out under the control of the scanning circuit 7. An output terminal of the video processing circuit 6 is connected to an output terminal 8 of the television camera 2.

To automatically set up the television camera 2, the output terminal of the video processing circuit 6 is connected to the (+) input terminal of the stage 9. Stage 9 also has a (-) input terminal from which it supplies reference information. This stage 9 is a microcomputer (μc) 1
combined with 0. The output/input terminals of this microcomputer 10 are labeled T ₁ , T ₂ . . . T _o . The difference information between the (+) input terminal and the (-) input terminal is converted into correction information as error information by the ninth and microcomputer 10, and is output to the output terminal. Stage 9 is on/
This correction information is input to the input terminal of the camera memory 11 via the off switch 12. Camera memory 11 has a control input/output terminal connected to terminal T ₁ of microcomputer 10 . The switching input terminal of the switch 12 is connected to the output terminal T ₂ of the microcomputer 10. An output terminal for outputting correction information of the camera memory 11 is coupled to input terminals of the video processing circuit 6 and the scanning circuit 7. In this example, this combination is performed via an adder circuit 13. Adder circuit 13 has two (+) input terminals connected to the output terminals of camera memory 11 and lens memory 14, respectively. Therefore, the correction information regarding the television camera stored in the camera memory and the correction information regarding the lens system stored in the lens memory are combined by the addition circuit 13, and the correction information for the lens system-camera combination as a whole is obtained. will be created and supplied to the video processing circuit and scanning circuit. The output terminal carrying the correction information of stage 9 is coupled to the input terminal of lens memory 14 via an on/off switch 15 and a subtraction circuit 16. Switch 15 has a switching input terminal connected to terminal _T3 . The lens memory 14 has a control input/output terminal connected to terminal _T4 . The subtraction circuit 16 has a (+) input terminal connected to the switch 15 and a (-) input terminal connected to the output terminal of the camera memory 11. An additional separate memory 17 can be provided between the output terminal of stage 9 and the (+) input terminal of subtraction circuit 16 as described above. and,
This memory 17 has a control input/output connected to terminal T ₅ .
It has an output terminal.

In order to supply the above-mentioned correction difference information from the subtraction circuit 16 to the lens memory 14, an internal test pattern 18 is created inside the television camera 2.
and optical path blocking means 19 are provided. The (mechanical) coupling means 20 are shown in the figure. The internal test pattern 18 is in the form of a rotatable slide,
This may be illuminated by the light source 21. Alternatively, the optical path blocking means 19 can also be provided between the lens system 4 and this rotatable slide.

In the accompanying drawings, switch 15 is shown in a closed state. In this state, the information based on the external test pattern 1 is processed in the television camera 2 as described above. Prior to this state, the internal test pattern 18 is the optical path 3 behind the lens system 4.
The optical path 3 was blocked by the optical path blocking means 19. In this pre-stage state, the switch 12 was closed. The result is that the setup method is performed in the two stages described above.

As explained above, according to the present invention, since the test camera itself has an internal test pattern built-in for generating correction information regarding the camera, it is possible to configure correction information to be displayed on the camera using the internal test pattern. In addition, the external test pattern is imaged through the lens system to generate correction information for the entire lens system-camera combination, and the previously obtained correction information regarding the camera is subtracted from this correction information to perform correction regarding the lens system. Information can be easily sought.

Furthermore, the television camera according to the present invention comprises:
Since it has an internal test pattern used to create correction information for the camera itself, a means for arranging the internal test pattern in the optical path, and a means for selectively illuminating the internal test pattern, the operator can make corrections related to the camera. Information can be generated. As a result, by using a combination of lens systems having lens memories that store lens correction signals, correction information for the entire lens system-camera combination can be easily created.

Furthermore, according to the present invention, since the operator can create correction information for the camera and lens system, the operator can refresh the correction information stored in the lens memory and camera memory, and as a result, the correction information due to aging etc. Changes can be easily corrected.

[Brief explanation of the drawing]

The attached drawing is a block diagram of a television camera according to the present invention. DESCRIPTION OF SYMBOLS 1... External test pattern, 2... Television camera, 3... Optical path, 4... Lens system, 5... Pickup device, 6... Video processing circuit, 7... Scanning circuit, 8
... Output terminal of television camera 2, 9... stage, 1
0... Microcomputer, 11... Camera memory, 12... On/off switch, 13... Addition circuit, 14... Lens memory, 15... On/off switch, 16... Subtraction circuit, 17... Memory, 18... Internal test pattern, 19... Optical path Blocking means, 2
0...Connection means, 21...Light source.

Claims (1)

[Claims] 1. When creating lens system correction information for use in multiple television cameras using a test camera that has a lens system and an imaging device on the optical path, it is possible to: An internal test pattern is placed in the optical path between the lens system and the imaging device, an internal test pattern is imaged by a test camera to create an internal test pattern correction signal, and the internal test pattern correction signal is stored in a camera memory. image an external test pattern with a test camera through a lens system to create an external test pattern correction signal, and subtract an internal test pattern correction signal from the external test pattern correction signal to represent correction information of the lens system. A method for creating lens system correction information, the method comprising: generating a lens system correction signal; and storing the lens system correction signal in a lens memory. 2. The lens system correction information creation method according to claim 1, further comprising the step of temporarily storing the correction signal in the external test pattern in an auxiliary memory.